PurpleSkyz

by Ian Greenhalgh, Britain with Jeff Smith, USA

Two weeks ago a devastating explosion took place in the port city of Tianjin, China. Official reports claimed a chemical storage facility had caught fire and exploded. Mobile phone footage taken by residents showed an enormous blast and fireball.

Within days, aerial photos revealed the stunning extent of the damage. A steaming black crater marks ground zero, while the apocalyptic surrounding landscape is charred and flattened. Rows of burnt-out cars and twisted shipping containers stretch into the distance on all sides.

The extent of the devastation is such that it must have been a very big bang indeed.

The total burned area spans 20,000 square meters and continues to be dangerous—more explosions were reported by Chinese authorities on the 15th of August. Residents within a 3-mile radius have been relocated; at least 85 victims of the accident have been reported dead.

We were immediately suspicious, such huge explosions have to be viewed with suspicion these days when tactical nuclear weapons can and are used with alarming frequency – 9-11, The Khobar Towers, the Haiti Earthquake and most recently, air dropped on Yemen.

Massive devastation over a wide area.

The mobile phone as radiation detector

The key clue that allowed us to identify the use of a nuke in Yemen was the presence of scintillating pixels – white dots that flashed on and off briefly in the mobile phone videos of the explosion. The CCD imaging sensor within the camera phone is being struck by radiation thus causing a pixel to overload and appear white; in this way a mobile phone can serve double duty as a crude but effective radiation detector.

When the Tianjin blast occurred I immediately looked at the mobile phone footage of the blast and tried to find scintillating pixels; I couldn’t find any, but the huge white hot fireball and sheer size of the blast effect apparent in the footage (shaken buildings, breaking windows etc.) certainly didn’t feel like a conventional explosion to my relatively untrained eyes.

It was actually VT Contributor and expert on all things nuclear, Jeff Smith who taught us about scintillating pixels and the use of a mobile phone camera to detect radiation; therefore I consulted him about the lack of scintillation in the Tianjin footage:

Scintillation is based on the distance from the blast. The farther you get away from the blast the less neutron exposure you get. CCD Cameras will detect scintillation but only at high levels. They are not sensitive to far field radiation patterns. All CCD cameras were too far away to be sensitive enough to show scintillation properly.

So you have to look at the white out in the centre of the photo. This is where the brightness is so great that it overloads the ccd pickup chip causing a clipping effect. The fact that the fireball was whited out or clipped indicates that the colour temperature was over 4,000 degrees C. Only achievable in a nuclear blast. The cameras auto gain circuit clips the video level for being too bright so you get a white out on the screen.

The fireball with white hot centre.

No scintillation but a clear piece of evidence indicating a nuclear explosion in the form of the huge white fireball – once again, mobile phone footage proves useful in deciphering the truth.

The parking lots full of toasted cars

As reports and images became available, we studied them carefully for evidence of the use of a nuclear weapon and sadly, it was not long before we found it – the first big clue coming with the pictures of the thousands of toasted cars that looked eerily like those seen on 9-11.

Thousands of burnt out Volkswagen Beetles close to ground zero in Tianjin.

While a layman like myself can recognise the overall similarity, it takes an expert to fully analyse the evidence contained in the pictures; luckily, at VT we have such an expert in the erstwhile Jeff Smith who provided the following analysis:

Normal people are not trained in what to look at so they simply ignore the obvious. However, once you see enough explosions like this you begin to spot the artefacts in the photos real fast. Unfortunately all of these people that know this stuff usually work for the government. Just like I did.

The big clue is in the ash produced and the exploding radiators on the cars. They show the radiation and the blast patterns the best. All melted rubber, glass, and aluminium but no melted steel? This tells you it is from radiation and not from a gasoline fire. Temps between 1500 degrees C for melting aluminium and less than 3,000 degrees C for melting steel. Everything organic ashes below 450 degrees C.

This had a plasma fireball that was over 4,000C! Only a nuke can do that. The clue is in the white ash leftover from the thermal blast.

G. Yellow Volkswagen Beetle cars untouched due to location indicating radiation shielding from a nearby building. Just like on 911….

H. Finally and most important is all of the nano particle sized ash on the ground everywhere. Purple haze in photo is an indication of toxic levels of the gases fluorine, chlorine and sodium.

Conclusion; The damage to the cars was produced by neutron radiation damage and not by conventional explosives or a fuel-air explosion. The distance from ground zero is too great for a standard blast to melt the glass and tires. Also the cars fuel tanks were shielded from the heat of the ignition source.

Purple haze indicating the presence of toxic levels of the gases fluorine, chlorine and sodium.

So there you have it, the ‘smoking gun’ evidence of a nuke is to be found among the smoking wreckage of those incinerated cars. However, the pictures of burnt out cars contain more evidence to be analysed before we move on to the other evidence.

The melted radiators and the role of Freon

As you can clearly see in the picture below, the radiator of this vehicle has been completely destroyed, incinerated into ash. Only the steel top plate remains, all of the aluminium and copper of the radiator core have been turned into a pile of ash. Once again, our resident expert Jeff Smith was able to provide insight and analysis of what we are seeing:

Incinerated remains of a car close to ground zero.

All of the radiators exploded from Freon decomposition into methane, deuterium fluoride, and phosgene gas; thus causing engine fires – note the melted hoods and also how overpressure from an air burst explosion has compressed the hoods of the cars.

The copper-clad/aluminium automotive radiator is transparent to nuclear radiation. It acts as a black body hollow-ram neutron reflector and functions just exactly like its bigger brother the two staged Teller-Ulman H-bomb. What this means is if you put DT gas or 2HF (Freon) in a vacuum chamber such as a car radiator, you reduce its density thus it take less energy to either split it or fuse it when exposed to neutrons, Gamma-rays or even soft x-rays from a nearby nuclear explosion – if the blast is large enough or close enough.

This forms the basis of a micro nuclear explosive device, with ignition temperatures high enough to melt just about anything that comes in contact with it. The key is in the lower density of the gas making compression of it a lot easier. This explains all of the melted car air conditioning radiators and follow on fires. Also the lack of fallout.

Here you can actually see the radiators at the front of the cars are on fire but the rear of the cars are untouched.

See Appendix A.

The Crater at Ground Zero

Once again, Jeff Smith was able to provide detailed analyses of the available imagery of the blast crater at ground zero and the damage to the surrounding area. Jeff along with Jim stone and others stated that:

This was NOT an accident, the fracture pattern around the crater proves a to be a shallow sub ground burst. If it was a sub ground burst, then a small nuclear weapon is the biggest possibility because once a nuke has to push dirt, the blinding flash will not be seen. A slightly subsurface detonation would explain why camera sensors did not get strange artefacts. And if it was not a nuke, it was something else incredibly huge, but not a fuel air bomb because fuel air bombs will not leave craters. They also leave an oily carbide residue on everything.

Even my layman’s eye can immediately tell that the explosion that caused this level of devastation was far beyond a mere explosion of stored chemicals. Also, there were no storage buildings at ground zero, just some stacks of shipping containers. Also, it is obvious to me that immense heat was present – look at the gray-white ash everywhere. Jeff was able to explain what I was seeing in these disturbing images:

A little bit more of a detailed explanation: If the blast happened at ground level, almost all of the energy would go upwards and the blast would not have made a large deep crater, especially one large enough and deep enough to make that lake. If you look to the right hand side of the lake, you can see fracture patterns in the earth, which were caused by the earth being compressed sideways and not downwards. This would only be done with a sub surface blast. After the blast, the earth bounced back towards the centre of the lake, which opened up the cracks.

Look closely at the ground around the lake. Those who claimed it was not a nuke cited the fact that if it was, everything around the crater would be vaporized and wiped clean. Now that we have the real crater pic from the big blast, YEP, it matches that perfectly. Take a look at the containers laying in the lower left corner of this picture – they have no paint or colour, which means they had the surfaces incinerated by intense heat only a nuke or other super weapon would reach. If this was a carbide blast, they would be black or have their original colours to some degree, complete colour change to only gray proves this explosion was FREAKING HOT.

That type and size of blast crater will only happen if a massive bomb goes off a few feet underground, such as a tactical nuke in a drain pipe which leaves scant few alternative options. No chemical blast did that, PERIOD. The building that is still standing in the upper right hand side of the frame is a typical example of what is left after a nuclear test, concrete buildings seldom get levelled, but they do get gutted by nuclear blasts. Just look through pictures of the soviet nuclear tests and you will see this. Bottom line? The aftermath is completely consistent with a nuclear blast.

Even to the untrained eye, the imagery of the aftermath of this awful event cannot be mistaken as anything other than horriffic; when you also have expert testimony that explains the true nature of what you are seeing the imagery becomes even more shocking and disturbing. Destruction on this scale will become commonplace if the perpetrators are allowed to get away with this as it will signal to all parties possessed of tactical nuclear weapons that it is possible to put them to use without disclosure of that fact by the media. Perhaps more concerning is China’s silence on the nuclear aspect of this great crime – they are still sticking to their story of fire setting off explosions of stored chemicals. As we have shown, this story is about as credible as the one about hijacking airliners with boxcutters; given state control of the media in China, it might be a while before people learn the truth.

PurpleSkyz

Admin

Posts : 71309Join date : 2012-01-04Location : Woodstock Nation

Identifying the type of weapon and Seismology of the eventNow we have established that a nuclear explosion took place, let us examine more closely the nature of that explosion. One important question is the delivery method – was it a strike by a cruise missile or was it a bomb hidden inside a shipping container? Or is there another answer to this question? The crater strongly indicates the explosion was sub-surface which appears to rule out the bomb having been smuggled into Tianjin in a shipping container. It does not rule out a cruise missile strike however – the ground in this area is very soft, alluvial deposits of soft silts and clays deposited over time by the nearby river. A cruise missile impacting this soft ground at over 500mph would surely penetrate to some depth; if a delayed action fuse was fitted to the warhead, this would create an shallow underground explosion. Jeff Smith provides further analysis:Note the crater is about 400 feet wide as measured by comparison to the standard shipping container sizes of 40 feet. The crater is a complex crater with a cardioid shape indicating a very low altitude or surface contact blast. Side ways compression of the soil indicates some ground penetration. Penetration depth of ground is based on soil type and burst height. Horizontal crater size is roughly equal to ( for every 100 feet, 1 Kiloton in size) see charts. This would put the blast size depending on air burst altitude to be between 3 and 5 kilotons of explosive power.Satellite image of Tianjin with overlay of blast radius.See Appendix B.If it was a low altitude air burst, ground coupling will be less showing a smaller Richter scale reading than usual. The only question is the fallout issue. Was there any and of what type. Since it rained after the blast most of the fallout went out to sea proven by the massive fish kill in the bay. The safety zone was set at 3 kilometres. This is a correct value for small tactical nuke fallout range. 1 KM per KT. The only other question was it a uranium weapon a plutonium based weapon or other i.e. a fusion weapon? Uranium cannot be traced very well but a PU based weapon can be traced down to the reactor that made it and the chemical separation process that was used. Firemen were shown carrying radiation and poisonous gas detectors. Given the 3km evacuation zone we can assume an explosive yield of around 3 kilotons. A typical cruise missile nuclear warhead such as the Israeli ‘Popeye’ carries 6 kilograms of plutonium; using the rule of thumb of 1 kiloton yield per kilogram of plutonium, the size of the explosion correlates with the yield of a typical cruise missile warhead.Jeff also noticed that a secondary blast took place; this is another indicator of the nuclear nature of this event, as Jeff explains:Well it looks like there were two major blasts not just one. There are two sections of the video where the blast whites out the entire camera. This is the original neutron burst going off; everything else is a secondary or the atmosphere heating up and burning.Note: The reaction caused, a sustained glowing in the sky which is a well known indicator of a nuclear explosion. Non-nuclear weapons do not provide a sustained “Sun-like” illumination because they do not have enough energy to ignite the oxygen and nitrogen in the atmosphere.Another aspect that requires study is the seismology readings of the event.. Once again, Jeff provides some insight:The first blast registered 2.3 on the Richter scale and the second 2.9. Eyewitnesses described what felt like a quake. USGS geophysicist John Bellini says seismographs detect man-made explosions in quarries all the time, but usually surface explosions are not detected very well because most of their energy dissipates upward into the air. The fact is that the Tianjin explosions registered a seismographic event that had as much energy as a small earthquake. One can reasonably conclude that unlike a surface explosion of chemicals, this kinetic energy released underground was caused by a powerful penetration of the surface.In this article we have tried to provide a thorough but clear and concise analysis of the available evidence and show that it is clear that this was no simple fire in a chemical storage depot that resulted in an explosion but rather it was the detonation of a nuclear weapon of unknown type by an unknown party. We will examine the who and why in a follow-up article.This is a very significant event that will undoubtedly prove to be of great importance in subsequent world events. In many ways, this is China’s 9-11.Let us all hope that unlike 9-11, the Nuking of Tianjin does not become the cassus belli for a whole series of unjustified, brutal and bloody conflicts.One thing is already very clearly illustrated by this tragic event – the gloves are most definitely off when it comes to the use of tactical nuclear weapons; we are living in an new nuclear age where a great number of countries possess the means to create and deploy tactical nukes and most worrying of all, these low yield weapons can be used and have already been used without fear of mutually assured destruction; the doctrine that prevented the Cold War from going nuclear. This makes the world a much more dangerous place and undoubtedly means we will see many more nuclear explosions in future.There is an old Chinese curse – “may you live in interesting times”; these are certainly ‘interesting’ times for anyone who is paying attention to events in China.See Appendix C for further reading and reference materials.

Appendix A:

An introduction to the physical principles of thermonuclear explosive devices would be incomplete did it not give at least a cursory overview of the different approaches to igniting thermonuclearmicro-explosions.A thermonuclear micro-explosion is an explosive release of thermonuclear energy many orders of magnitude smaller than from a thermonuclear weapon. To achieve this goal, the fission trigger must be replaced by some other means of producing the required ignition temperature, but in a much smaller volume and without the large energy release.The possibility of thermonuclear micro-explosions is itself a consequence of two facts: first, the fact that the minimum volume to make a thermonuclear explosion is given by the range of the chargedfusion products \ 0 , and, second, scaling. At solid densities and thermonuclear temperatures the range is of the order of a few centimeters and, is inversely proportional to the density p of the thermonuclear explosive. We can therefore write for this range.X0 = a/p, a — const.For the DT reaction we easily find that the minimum ignition energy is about 108 Joules. To obtain a useful gain the output energy should be at least ~ 100 times larger, that is, 1010 Joules = 10 n erg, which corresponds to the explosive power of approximately 2 tons of TNT.The ignition energy can be substantially reduced by increasing the density of the thermonuclear explosive. However, since for p > p, the compression to higher densities also requires energy, the input energy is in reality larger than the value given by Eq. (132).The time r to deposit the energy in the target is given by r ^ r/v, where v is the thermal expansion velocity of the thermonuclear plasma of radius r, which is a function only of the temperature.